/* * This file is part of the coreboot project. * * Copyright 2013 Google Inc. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; version 2 of the License. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. */ #include #include #include #include #include #include #include #include #include #include #include static void sdram_patch(uintptr_t addr, uint32_t value) { if (addr) write32((uint32_t *)addr, value); } static void writebits(uint32_t value, uint32_t *addr, uint32_t mask) { clrsetbits_le32(addr, mask, (value & mask)); } /* PMC must be configured before clock-enable and de-reset of MC/EMC. */ static void sdram_configure_pmc(const struct sdram_params *param, struct tegra_pmc_regs *regs) { /* VDDP Select */ write32(®s->vddp_sel, param->PmcVddpSel); udelay(param->PmcVddpSelWait); /* Set DDR pad voltage */ writebits(param->PmcDdrPwr, ®s->ddr_pwr, PMC_DDR_PWR_VAL_MASK); /* Set package and DPD pad control */ writebits(param->PmcDdrCfg, ®s->ddr_cfg, (PMC_DDR_CFG_PKG_MASK | PMC_DDR_CFG_IF_MASK | PMC_DDR_CFG_XM0_RESET_TRI_MASK | PMC_DDR_CFG_XM0_RESET_DPDIO_MASK)); /* Turn on MEM IO Power */ writebits(param->PmcNoIoPower, ®s->no_iopower, (PMC_NO_IOPOWER_MEM_MASK | PMC_NO_IOPOWER_MEM_COMP_MASK)); write32(®s->reg_short, param->PmcRegShort); } static void sdram_start_clocks(const struct sdram_params *param) { u32 is_same_freq = (param->McEmemArbMisc0 & MC_EMEM_ARB_MISC0_MC_EMC_SAME_FREQ_MASK) ? 1 : 0; clock_sdram(param->PllMInputDivider, param->PllMFeedbackDivider, param->PllMSelectDiv2, param->PllMSetupControl, param->PllMPDLshiftPh45, param->PllMPDLshiftPh90, param->PllMPDLshiftPh135, param->PllMKVCO, param->PllMKCP, param->PllMStableTime, param->EmcClockSource, is_same_freq); } static void sdram_deassert_clock_enable_signal(const struct sdram_params *param, struct tegra_pmc_regs *regs) { clrbits_le32(®s->por_dpd_ctrl, PMC_POR_DPD_CTRL_MEM0_HOLD_CKE_LOW_OVR_MASK); udelay(param->PmcPorDpdCtrlWait); } static void sdram_deassert_sel_dpd(const struct sdram_params *param, struct tegra_pmc_regs *regs) { clrbits_le32(®s->por_dpd_ctrl, (PMC_POR_DPD_CTRL_MEM0_ADDR0_CLK_SEL_DPD_MASK | PMC_POR_DPD_CTRL_MEM0_ADDR1_CLK_SEL_DPD_MASK)); /* * Note NVIDIA recommended to always do 10us delay here and ignore * BCT.PmcPorDpdCtrlWait. * */ udelay(10); } static void sdram_set_swizzle(const struct sdram_params *param, struct tegra_emc_regs *regs) { write32(®s->swizzle_rank0_byte_cfg, param->EmcSwizzleRank0ByteCfg); write32(®s->swizzle_rank0_byte0, param->EmcSwizzleRank0Byte0); write32(®s->swizzle_rank0_byte1, param->EmcSwizzleRank0Byte1); write32(®s->swizzle_rank0_byte2, param->EmcSwizzleRank0Byte2); write32(®s->swizzle_rank0_byte3, param->EmcSwizzleRank0Byte3); write32(®s->swizzle_rank1_byte_cfg, param->EmcSwizzleRank1ByteCfg); write32(®s->swizzle_rank1_byte0, param->EmcSwizzleRank1Byte0); write32(®s->swizzle_rank1_byte1, param->EmcSwizzleRank1Byte1); write32(®s->swizzle_rank1_byte2, param->EmcSwizzleRank1Byte2); write32(®s->swizzle_rank1_byte3, param->EmcSwizzleRank1Byte3); } static void sdram_set_pad_controls(const struct sdram_params *param, struct tegra_emc_regs *regs) { /* Program the pad controls */ write32(®s->xm2cmdpadctrl, param->EmcXm2CmdPadCtrl); write32(®s->xm2cmdpadctrl2, param->EmcXm2CmdPadCtrl2); write32(®s->xm2cmdpadctrl3, param->EmcXm2CmdPadCtrl3); write32(®s->xm2cmdpadctrl4, param->EmcXm2CmdPadCtrl4); write32(®s->xm2cmdpadctrl5, param->EmcXm2CmdPadCtrl5); write32(®s->xm2dqspadctrl, param->EmcXm2DqsPadCtrl); write32(®s->xm2dqspadctrl2, param->EmcXm2DqsPadCtrl2); write32(®s->xm2dqspadctrl3, param->EmcXm2DqsPadCtrl3); write32(®s->xm2dqspadctrl4, param->EmcXm2DqsPadCtrl4); write32(®s->xm2dqspadctrl5, param->EmcXm2DqsPadCtrl5); write32(®s->xm2dqspadctrl6, param->EmcXm2DqsPadCtrl6); write32(®s->xm2dqpadctrl, param->EmcXm2DqPadCtrl); write32(®s->xm2dqpadctrl2, param->EmcXm2DqPadCtrl2); write32(®s->xm2dqpadctrl3, param->EmcXm2DqPadCtrl3); write32(®s->xm2clkpadctrl, param->EmcXm2ClkPadCtrl); write32(®s->xm2clkpadctrl2, param->EmcXm2ClkPadCtrl2); write32(®s->xm2comppadctrl, param->EmcXm2CompPadCtrl); write32(®s->xm2vttgenpadctrl, param->EmcXm2VttGenPadCtrl); write32(®s->xm2vttgenpadctrl2, param->EmcXm2VttGenPadCtrl2); write32(®s->xm2vttgenpadctrl3, param->EmcXm2VttGenPadCtrl3); write32(®s->ctt_term_ctrl, param->EmcCttTermCtrl); } static void sdram_trigger_emc_timing_update(struct tegra_emc_regs *regs) { write32(®s->timing_control, EMC_TIMING_CONTROL_TIMING_UPDATE); } static void sdram_init_mc(const struct sdram_params *param, struct tegra_mc_regs *regs) { /* Initialize MC VPR settings */ write32(®s->display_snap_ring, param->McDisplaySnapRing); write32(®s->video_protect_bom, param->McVideoProtectBom); write32(®s->video_protect_bom_adr_hi, param->McVideoProtectBomAdrHi); write32(®s->video_protect_size_mb, param->McVideoProtectSizeMb); write32(®s->video_protect_vpr_override, param->McVideoProtectVprOverride); write32(®s->video_protect_vpr_override1, param->McVideoProtectVprOverride1); write32(®s->video_protect_gpu_override_0, param->McVideoProtectGpuOverride0); write32(®s->video_protect_gpu_override_1, param->McVideoProtectGpuOverride1); /* Program SDRAM geometry paarameters */ write32(®s->emem_adr_cfg, param->McEmemAdrCfg); write32(®s->emem_adr_cfg_dev0, param->McEmemAdrCfgDev0); write32(®s->emem_adr_cfg_dev1, param->McEmemAdrCfgDev1); /* Program bank swizzling */ write32(®s->emem_bank_swizzle_cfg0, param->McEmemAdrCfgBankMask0); write32(®s->emem_bank_swizzle_cfg1, param->McEmemAdrCfgBankMask1); write32(®s->emem_bank_swizzle_cfg2, param->McEmemAdrCfgBankMask2); write32(®s->emem_bank_swizzle_cfg3, param->McEmemAdrCfgBankSwizzle3); /* Program external memory aperature (base and size) */ write32(®s->emem_cfg, param->McEmemCfg); /* Program SEC carveout (base and size) */ write32(®s->sec_carveout_bom, param->McSecCarveoutBom); write32(®s->sec_carveout_adr_hi, param->McSecCarveoutAdrHi); write32(®s->sec_carveout_size_mb, param->McSecCarveoutSizeMb); /* Program MTS carveout (base and size) */ write32(®s->mts_carveout_bom, param->McMtsCarveoutBom); write32(®s->mts_carveout_adr_hi, param->McMtsCarveoutAdrHi); write32(®s->mts_carveout_size_mb, param->McMtsCarveoutSizeMb); /* Program the memory arbiter */ write32(®s->emem_arb_cfg, param->McEmemArbCfg); write32(®s->emem_arb_outstanding_req, param->McEmemArbOutstandingReq); write32(®s->emem_arb_timing_rcd, param->McEmemArbTimingRcd); write32(®s->emem_arb_timing_rp, param->McEmemArbTimingRp); write32(®s->emem_arb_timing_rc, param->McEmemArbTimingRc); write32(®s->emem_arb_timing_ras, param->McEmemArbTimingRas); write32(®s->emem_arb_timing_faw, param->McEmemArbTimingFaw); write32(®s->emem_arb_timing_rrd, param->McEmemArbTimingRrd); write32(®s->emem_arb_timing_rap2pre, param->McEmemArbTimingRap2Pre); write32(®s->emem_arb_timing_wap2pre, param->McEmemArbTimingWap2Pre); write32(®s->emem_arb_timing_r2r, param->McEmemArbTimingR2R); write32(®s->emem_arb_timing_w2w, param->McEmemArbTimingW2W); write32(®s->emem_arb_timing_r2w, param->McEmemArbTimingR2W); write32(®s->emem_arb_timing_w2r, param->McEmemArbTimingW2R); write32(®s->emem_arb_da_turns, param->McEmemArbDaTurns); write32(®s->emem_arb_da_covers, param->McEmemArbDaCovers); write32(®s->emem_arb_misc0, param->McEmemArbMisc0); write32(®s->emem_arb_misc1, param->McEmemArbMisc1); write32(®s->emem_arb_ring1_throttle, param->McEmemArbRing1Throttle); write32(®s->emem_arb_override, param->McEmemArbOverride); write32(®s->emem_arb_override_1, param->McEmemArbOverride1); write32(®s->emem_arb_rsv, param->McEmemArbRsv); /* Program extra snap levels for display client */ write32(®s->dis_extra_snap_levels, param->McDisExtraSnapLevels); /* Trigger MC timing update */ write32(®s->timing_control, MC_TIMING_CONTROL_TIMING_UPDATE); /* Program second-level clock enable overrides */ write32(®s->clken_override, param->McClkenOverride); /* Program statistics gathering */ write32(®s->stat_control, param->McStatControl); } static void sdram_init_emc(const struct sdram_params *param, struct tegra_emc_regs *regs) { /* Program SDRAM geometry parameters */ write32(®s->adr_cfg, param->EmcAdrCfg); /* Program second-level clock enable overrides */ write32(®s->clken_override, param->EmcClkenOverride); /* Program EMC pad auto calibration */ write32(®s->auto_cal_interval, param->EmcAutoCalInterval); write32(®s->auto_cal_config2, param->EmcAutoCalConfig2); write32(®s->auto_cal_config3, param->EmcAutoCalConfig3); write32(®s->auto_cal_config, param->EmcAutoCalConfig); udelay(param->EmcAutoCalWait); } static void sdram_set_emc_timing(const struct sdram_params *param, struct tegra_emc_regs *regs) { /* Program EMC timing configuration */ write32(®s->cfg_2, param->EmcCfg2); write32(®s->cfg_pipe, param->EmcCfgPipe); write32(®s->dbg, param->EmcDbg); write32(®s->cmdq, param->EmcCmdQ); write32(®s->mc2emcq, param->EmcMc2EmcQ); write32(®s->mrs_wait_cnt, param->EmcMrsWaitCnt); write32(®s->mrs_wait_cnt2, param->EmcMrsWaitCnt2); write32(®s->fbio_cfg5, param->EmcFbioCfg5); write32(®s->rc, param->EmcRc); write32(®s->rfc, param->EmcRfc); write32(®s->rfc_slr, param->EmcRfcSlr); write32(®s->ras, param->EmcRas); write32(®s->rp, param->EmcRp); write32(®s->r2r, param->EmcR2r); write32(®s->w2w, param->EmcW2w); write32(®s->r2w, param->EmcR2w); write32(®s->w2r, param->EmcW2r); write32(®s->r2p, param->EmcR2p); write32(®s->w2p, param->EmcW2p); write32(®s->rd_rcd, param->EmcRdRcd); write32(®s->wr_rcd, param->EmcWrRcd); write32(®s->rrd, param->EmcRrd); write32(®s->rext, param->EmcRext); write32(®s->wext, param->EmcWext); write32(®s->wdv, param->EmcWdv); write32(®s->wdv_mask, param->EmcWdvMask); write32(®s->quse, param->EmcQUse); write32(®s->quse_width, param->EmcQuseWidth); write32(®s->ibdly, param->EmcIbdly); write32(®s->einput, param->EmcEInput); write32(®s->einput_duration, param->EmcEInputDuration); write32(®s->puterm_extra, param->EmcPutermExtra); write32(®s->puterm_width, param->EmcPutermWidth); write32(®s->puterm_adj, param->EmcPutermAdj); write32(®s->cdb_cntl_1, param->EmcCdbCntl1); write32(®s->cdb_cntl_2, param->EmcCdbCntl2); write32(®s->cdb_cntl_3, param->EmcCdbCntl3); write32(®s->qrst, param->EmcQRst); write32(®s->qsafe, param->EmcQSafe); write32(®s->rdv, param->EmcRdv); write32(®s->rdv_mask, param->EmcRdvMask); write32(®s->qpop, param->EmcQpop); write32(®s->ctt, param->EmcCtt); write32(®s->ctt_duration, param->EmcCttDuration); write32(®s->refresh, param->EmcRefresh); write32(®s->burst_refresh_num, param->EmcBurstRefreshNum); write32(®s->pre_refresh_req_cnt, param->EmcPreRefreshReqCnt); write32(®s->pdex2wr, param->EmcPdEx2Wr); write32(®s->pdex2rd, param->EmcPdEx2Rd); write32(®s->pchg2pden, param->EmcPChg2Pden); write32(®s->act2pden, param->EmcAct2Pden); write32(®s->ar2pden, param->EmcAr2Pden); write32(®s->rw2pden, param->EmcRw2Pden); write32(®s->txsr, param->EmcTxsr); write32(®s->txsrdll, param->EmcTxsrDll); write32(®s->tcke, param->EmcTcke); write32(®s->tckesr, param->EmcTckesr); write32(®s->tpd, param->EmcTpd); write32(®s->tfaw, param->EmcTfaw); write32(®s->trpab, param->EmcTrpab); write32(®s->tclkstable, param->EmcTClkStable); write32(®s->tclkstop, param->EmcTClkStop); write32(®s->trefbw, param->EmcTRefBw); write32(®s->odt_write, param->EmcOdtWrite); write32(®s->odt_read, param->EmcOdtRead); write32(®s->fbio_cfg6, param->EmcFbioCfg6); write32(®s->cfg_dig_dll, param->EmcCfgDigDll); write32(®s->cfg_dig_dll_period, param->EmcCfgDigDllPeriod); /* Don't write bit 1: addr swizzle lock bit. Written at end of sequence. */ write32(®s->fbio_spare, param->EmcFbioSpare & 0xfffffffd); write32(®s->cfg_rsv, param->EmcCfgRsv); write32(®s->dll_xform_dqs0, param->EmcDllXformDqs0); write32(®s->dll_xform_dqs1, param->EmcDllXformDqs1); write32(®s->dll_xform_dqs2, param->EmcDllXformDqs2); write32(®s->dll_xform_dqs3, param->EmcDllXformDqs3); write32(®s->dll_xform_dqs4, param->EmcDllXformDqs4); write32(®s->dll_xform_dqs5, param->EmcDllXformDqs5); write32(®s->dll_xform_dqs6, param->EmcDllXformDqs6); write32(®s->dll_xform_dqs7, param->EmcDllXformDqs7); write32(®s->dll_xform_dqs8, param->EmcDllXformDqs8); write32(®s->dll_xform_dqs9, param->EmcDllXformDqs9); write32(®s->dll_xform_dqs10, param->EmcDllXformDqs10); write32(®s->dll_xform_dqs11, param->EmcDllXformDqs11); write32(®s->dll_xform_dqs12, param->EmcDllXformDqs12); write32(®s->dll_xform_dqs13, param->EmcDllXformDqs13); write32(®s->dll_xform_dqs14, param->EmcDllXformDqs14); write32(®s->dll_xform_dqs15, param->EmcDllXformDqs15); write32(®s->dll_xform_quse0, param->EmcDllXformQUse0); write32(®s->dll_xform_quse1, param->EmcDllXformQUse1); write32(®s->dll_xform_quse2, param->EmcDllXformQUse2); write32(®s->dll_xform_quse3, param->EmcDllXformQUse3); write32(®s->dll_xform_quse4, param->EmcDllXformQUse4); write32(®s->dll_xform_quse5, param->EmcDllXformQUse5); write32(®s->dll_xform_quse6, param->EmcDllXformQUse6); write32(®s->dll_xform_quse7, param->EmcDllXformQUse7); write32(®s->dll_xform_quse8, param->EmcDllXformQUse8); write32(®s->dll_xform_quse9, param->EmcDllXformQUse9); write32(®s->dll_xform_quse10, param->EmcDllXformQUse10); write32(®s->dll_xform_quse11, param->EmcDllXformQUse11); write32(®s->dll_xform_quse12, param->EmcDllXformQUse12); write32(®s->dll_xform_quse13, param->EmcDllXformQUse13); write32(®s->dll_xform_quse14, param->EmcDllXformQUse14); write32(®s->dll_xform_quse15, param->EmcDllXformQUse15); write32(®s->dll_xform_dq0, param->EmcDllXformDq0); write32(®s->dll_xform_dq1, param->EmcDllXformDq1); write32(®s->dll_xform_dq2, param->EmcDllXformDq2); write32(®s->dll_xform_dq3, param->EmcDllXformDq3); write32(®s->dll_xform_dq4, param->EmcDllXformDq4); write32(®s->dll_xform_dq5, param->EmcDllXformDq5); write32(®s->dll_xform_dq6, param->EmcDllXformDq6); write32(®s->dll_xform_dq7, param->EmcDllXformDq7); write32(®s->dll_xform_addr0, param->EmcDllXformAddr0); write32(®s->dll_xform_addr1, param->EmcDllXformAddr1); write32(®s->dll_xform_addr2, param->EmcDllXformAddr2); write32(®s->dll_xform_addr3, param->EmcDllXformAddr3); write32(®s->dll_xform_addr4, param->EmcDllXformAddr4); write32(®s->dll_xform_addr5, param->EmcDllXformAddr5); write32(®s->acpd_control, param->EmcAcpdControl); write32(®s->dsr_vttgen_drv, param->EmcDsrVttgenDrv); write32(®s->txdsrvttgen, param->EmcTxdsrvttgen); write32(®s->bgbias_ctl0, param->EmcBgbiasCtl0); /* * Set pipe bypass enable bits before sending any DRAM commands. * Note other bits in EMC_CFG must be set AFTER REFCTRL is configured. */ writebits(param->EmcCfg, ®s->cfg, (EMC_CFG_EMC2PMACRO_CFG_BYPASS_ADDRPIPE_MASK | EMC_CFG_EMC2PMACRO_CFG_BYPASS_DATAPIPE1_MASK | EMC_CFG_EMC2PMACRO_CFG_BYPASS_DATAPIPE2_MASK)); } static void sdram_patch_bootrom(const struct sdram_params *param, struct tegra_mc_regs *regs) { if (param->BootRomPatchControl & BOOT_ROM_PATCH_CONTROL_ENABLE_MASK) { uintptr_t addr = ((param->BootRomPatchControl & BOOT_ROM_PATCH_CONTROL_OFFSET_MASK) >> BOOT_ROM_PATCH_CONTROL_OFFSET_SHIFT); addr = BOOT_ROM_PATCH_CONTROL_BASE_ADDRESS + (addr << 2); write32((uint32_t *)addr, param->BootRomPatchData); write32(®s->timing_control, 1); } } static void sdram_set_dpd3(const struct sdram_params *param, struct tegra_pmc_regs *regs) { /* Program DPD request */ write32(®s->io_dpd3_req, param->PmcIoDpd3Req); udelay(param->PmcIoDpd3ReqWait); } static void sdram_set_dli_trims(const struct sdram_params *param, struct tegra_emc_regs *regs) { /* Program DLI trims */ write32(®s->dli_trim_txdqs0, param->EmcDliTrimTxDqs0); write32(®s->dli_trim_txdqs1, param->EmcDliTrimTxDqs1); write32(®s->dli_trim_txdqs2, param->EmcDliTrimTxDqs2); write32(®s->dli_trim_txdqs3, param->EmcDliTrimTxDqs3); write32(®s->dli_trim_txdqs4, param->EmcDliTrimTxDqs4); write32(®s->dli_trim_txdqs5, param->EmcDliTrimTxDqs5); write32(®s->dli_trim_txdqs6, param->EmcDliTrimTxDqs6); write32(®s->dli_trim_txdqs7, param->EmcDliTrimTxDqs7); write32(®s->dli_trim_txdqs8, param->EmcDliTrimTxDqs8); write32(®s->dli_trim_txdqs9, param->EmcDliTrimTxDqs9); write32(®s->dli_trim_txdqs10, param->EmcDliTrimTxDqs10); write32(®s->dli_trim_txdqs11, param->EmcDliTrimTxDqs11); write32(®s->dli_trim_txdqs12, param->EmcDliTrimTxDqs12); write32(®s->dli_trim_txdqs13, param->EmcDliTrimTxDqs13); write32(®s->dli_trim_txdqs14, param->EmcDliTrimTxDqs14); write32(®s->dli_trim_txdqs15, param->EmcDliTrimTxDqs15); write32(®s->ca_training_timing_cntl1, param->EmcCaTrainingTimingCntl1); write32(®s->ca_training_timing_cntl2, param->EmcCaTrainingTimingCntl2); sdram_trigger_emc_timing_update(regs); udelay(param->EmcTimingControlWait); } static void sdram_set_clock_enable_signal(const struct sdram_params *param, struct tegra_emc_regs *regs) { volatile uint32_t dummy = 0; clrbits_le32(®s->pin, (EMC_PIN_RESET_MASK | EMC_PIN_DQM_MASK | EMC_PIN_CKE_MASK)); /* * Assert dummy read of PIN register to ensure above write to PIN * register went through. 200 is the recommended value by NVIDIA. */ dummy |= read32(®s->pin); udelay(200 + param->EmcPinExtraWait); /* Deassert reset */ setbits_le32(®s->pin, EMC_PIN_RESET_INACTIVE); /* * Assert dummy read of PIN register to ensure above write to PIN * register went through. 200 is the recommended value by NVIDIA. */ dummy |= read32(®s->pin); udelay(500 + param->EmcPinExtraWait); /* Enable clock enable signal */ setbits_le32(®s->pin, EMC_PIN_CKE_NORMAL); /* * Assert dummy read of PIN register to ensure above write to PIN * register went through. 200 is the recommended value by NVIDIA. */ dummy |= read32(®s->pin); udelay(param->EmcPinProgramWait); if (!dummy) { die("Failed to program EMC pin."); } /* Send NOP (trigger) */ writebits(((1 << EMC_NOP_NOP_CMD_SHIFT) | (param->EmcDevSelect << EMC_NOP_NOP_DEV_SELECTN_SHIFT)), ®s->nop, EMC_NOP_NOP_CMD_MASK | EMC_NOP_NOP_DEV_SELECTN_MASK); /* Write mode registers */ write32(®s->emrs2, param->EmcEmrs2); write32(®s->emrs3, param->EmcEmrs3); write32(®s->emrs, param->EmcEmrs); write32(®s->mrs, param->EmcMrs); if (param->EmcExtraModeRegWriteEnable) { write32(®s->mrs, param->EmcMrwExtra); } } static void sdram_init_zq_calibration(const struct sdram_params *param, struct tegra_emc_regs *regs) { if ((param->EmcZcalWarmColdBootEnables & EMC_ZCAL_WARM_COLD_BOOT_ENABLES_COLDBOOT_MASK) == 1) { /* Need to initialize ZCAL on coldboot. */ write32(®s->zq_cal, param->EmcZcalInitDev0); udelay(param->EmcZcalInitWait); if ((param->EmcDevSelect & 2) == 0) { write32(®s->zq_cal, param->EmcZcalInitDev1); udelay(param->EmcZcalInitWait); } } else { udelay(param->EmcZcalInitWait); } } static void sdram_set_zq_calibration(const struct sdram_params *param, struct tegra_emc_regs *regs) { /* Start periodic ZQ calibration */ write32(®s->zcal_interval, param->EmcZcalInterval); write32(®s->zcal_wait_cnt, param->EmcZcalWaitCnt); write32(®s->zcal_mrw_cmd, param->EmcZcalMrwCmd); } static void sdram_set_refresh(const struct sdram_params *param, struct tegra_emc_regs *regs) { /* Insert burst refresh */ if (param->EmcExtraRefreshNum > 0) { uint32_t refresh_num = (1 << param->EmcExtraRefreshNum) - 1; writebits((EMC_REF_CMD_REFRESH | EMC_REF_NORMAL_ENABLED | (refresh_num << EMC_REF_NUM_SHIFT) | (param->EmcDevSelect << EMC_REF_DEV_SELECTN_SHIFT)), ®s->ref, (EMC_REF_CMD_MASK | EMC_REF_NORMAL_MASK | EMC_REF_NUM_MASK | EMC_REF_DEV_SELECTN_MASK)); } /* Enable refresh */ write32(®s->refctrl, (param->EmcDevSelect | EMC_REFCTRL_REF_VALID_ENABLED)); write32(®s->dyn_self_ref_control, param->EmcDynSelfRefControl); write32(®s->cfg, param->EmcCfg); write32(®s->sel_dpd_ctrl, param->EmcSelDpdCtrl); /* Write addr swizzle lock bit */ write32(®s->fbio_spare, param->EmcFbioSpare); /* Re-trigger timing to latch power saving functions */ sdram_trigger_emc_timing_update(regs); } static void sdram_enable_arbiter(const struct sdram_params *param) { /* TODO(hungte) Move values here to standalone header file. */ uint32_t *AHB_ARBITRATION_XBAR_CTRL = (uint32_t*)(0x6000c000 + 0xe0); setbits_le32(AHB_ARBITRATION_XBAR_CTRL, param->AhbArbitrationXbarCtrlMemInitDone << 16); } static void sdram_lock_carveouts(const struct sdram_params *param, struct tegra_mc_regs *regs) { /* Lock carveouts, and emem_cfg registers */ write32(®s->video_protect_reg_ctrl, param->McVideoProtectWriteAccess); write32(®s->emem_cfg_access_ctrl, MC_EMEM_CFG_ACCESS_CTRL_WRITE_ACCESS_DISABLED); write32(®s->sec_carveout_reg_ctrl, param->McSecCarveoutProtectWriteAccess); write32(®s->mts_carveout_reg_ctrl, param->McMtsCarveoutRegCtrl); } void sdram_init(const struct sdram_params *param) { struct tegra_pmc_regs *pmc = (struct tegra_pmc_regs*)TEGRA_PMC_BASE; struct tegra_mc_regs *mc = (struct tegra_mc_regs*)TEGRA_MC_BASE; struct tegra_emc_regs *emc = (struct tegra_emc_regs*)TEGRA_EMC_BASE; printk(BIOS_DEBUG, "Initializing SDRAM of type %d with %dKHz\n", param->MemoryType, clock_get_pll_input_khz() * param->PllMFeedbackDivider / param->PllMInputDivider / (1 + param->PllMSelectDiv2)); if (param->MemoryType != NvBootMemoryType_Ddr3) die("Unsupported memory type!\n"); sdram_configure_pmc(param, pmc); sdram_patch(param->EmcBctSpare0, param->EmcBctSpare1); sdram_start_clocks(param); sdram_patch(param->EmcBctSpare2, param->EmcBctSpare3); sdram_deassert_sel_dpd(param, pmc); sdram_set_swizzle(param, emc); sdram_set_pad_controls(param, emc); sdram_patch(param->EmcBctSpare4, param->EmcBctSpare5); sdram_trigger_emc_timing_update(emc); sdram_init_mc(param, mc); sdram_init_emc(param, emc); sdram_patch(param->EmcBctSpare6, param->EmcBctSpare7); sdram_set_emc_timing(param, emc); sdram_patch_bootrom(param, mc); sdram_set_dpd3(param, pmc); sdram_set_dli_trims(param, emc); sdram_deassert_clock_enable_signal(param, pmc); sdram_set_clock_enable_signal(param, emc); sdram_init_zq_calibration(param, emc); sdram_patch(param->EmcBctSpare8, param->EmcBctSpare9); sdram_set_zq_calibration(param, emc); sdram_patch(param->EmcBctSpare10, param->EmcBctSpare11); sdram_trigger_emc_timing_update(emc); sdram_set_refresh(param, emc); sdram_enable_arbiter(param); sdram_lock_carveouts(param, mc); sdram_lp0_save_params(param); } uint32_t sdram_get_ram_code(void) { struct tegra_pmc_regs *pmc = (struct tegra_pmc_regs*)TEGRA_PMC_BASE; return ((read32(&pmc->strapping_opt_a) & PMC_STRAPPING_OPT_A_RAM_CODE_MASK) >> PMC_STRAPPING_OPT_A_RAM_CODE_SHIFT); } /* returns total amount of DRAM (in MB) from memory controller registers */ int sdram_size_mb(void) { struct tegra_mc_regs *mc = (struct tegra_mc_regs *)TEGRA_MC_BASE; static int total_size = 0; if (total_size) return total_size; /* * This obtains memory size from the External Memory Aperture * Configuration register. Nvidia confirmed that it is safe to assume * this value represents the total physical DRAM size. */ total_size = (read32(&mc->emem_cfg) >> MC_EMEM_CFG_SIZE_MB_SHIFT) & MC_EMEM_CFG_SIZE_MB_MASK; printk(BIOS_DEBUG, "%s: Total SDRAM (MB): %u\n", __func__, total_size); return total_size; } uintptr_t sdram_max_addressable_mb(void) { return MIN(((uintptr_t)_dram/MiB) + sdram_size_mb(), 4096); }